Leaf Cuticular Wax Composition of a Genetically Diverse Collection of Lettuce ( L.) Cultivars Evaluated Under Field Conditions

Overview

Journal Heliyon

Specialty Social Sciences

Date 2024 Mar 11

PMID 38463774

Authors

Wenting Luo

Emmanuel Gonzalez

Ariyan Zarei

Sebastian Calleja

Bruno Rozzi

Jeffrey Demieville

Haiquan Li

Maria-Jose Truco

Dean Lavelle

Richard Michelmore

John M Dyer

Matthew A Jenks

Duke Pauli

Affiliations

Soon will be listed here.

Abstract

Cuticular waxes of plants impart tolerance to many forms of environmental stress and help shed dangerous human pathogens on edible plant parts. Although the chemical composition of waxes on a wide variety of important crops has been described, a detailed wax compositional analysis has yet to be reported for lettuce ( L.), one of the most widely consumed vegetables. We present herein the leaf wax content and composition of 12 genetically diverse lettuce cultivars sampled across five time points during their vegetative growth phase in the field. Mean total leaf wax amounts across all cultivars varied little over 28 days of vegetative growth, except for a notable decrease in total waxes following a major precipitation event, presumably due to wax degradation from wind and rain. All lettuce cultivars were found to contain a unique wax composition highly enriched in 22- and 24-carbon length 1-alcohols (docosanol and tetracosanol, respectively). In our report, the dominance of these shorter chain length 1-alcohols as wax constituents represents a relatively rare phenotype in plants. The ecological significance of these dominant and relatively short 1-alcohols is still unknown. Although waxes have been a target for improvement of various crops, no such work has been reported for lettuce. This study lays the groundwork for future research that aims to integrate cuticular wax characteristics of field grown plants into the larger context of lettuce breeding and cultivar development.

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